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Ring / ERL Compton e + Source for ILC

Ring / ERL Compton e + Source for ILC. Tsunehiko OMORI (KEK). PosiPol 2008 International Conference Center Hiroshima 16-June-2008. Today's Talk. 1. Laser-Compton e + source for ILC/CLIC. 2. Ring / ERL scheme for ILC. 3. Possible Parameters and Choices of Ring/ERL scheme.

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Ring / ERL Compton e + Source for ILC

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  1. Ring/ERL Compton e+ Source for ILC Tsunehiko OMORI (KEK) PosiPol 2008 International Conference Center Hiroshima 16-June-2008

  2. Today's Talk 1. Laser-Compton e+ source for ILC/CLIC. 2. Ring / ERL scheme for ILC 3. Possible Parameters and Choices of Ring/ERL scheme 4. Necessary R/Ds for Ring/ERL scheme 5. Apprications and PosiPol Collaboration 5. Summary

  3. Laser-Compton e+ source for ILC/CLIC

  4. Emax = 30 - 60 MeV Two ways to get pol. e+ (1) Helical Undurator e- beam E >150 GeV Undulator L > 200 m (2) Laser Compton

  5. Emax = 30 - 60 MeV Two ways to get pol. e+ (1) Helical Undurator e- beam E >150 GeV Undulator L > 200 m Our Proposal (2) Laser Compton

  6. Why Laser-Compton ? i) Positron Polarization. ii) Independence Undulator-base e+ : use e- main linac Problem on design, construction, commissioning, maintenance, Laser-base e+ : independent Easier construction, operation, commissioning, maintenance iii) Polarization flip @ 5Hz (for CLIC @ 50 Hz) iv) High polarization v) Low energy operation Undulator-base e+ : need deceleration Laser-base e+ : no problem

  7. Why Laser-Compton ? i) Positron Polarization. ii) Independence Undulator-base e+ : use e- main linac Problem on design, construction, commissioning, maintenance, Laser-base e+ : independent Easier construction, operation, commissioning, maintenance iii) Polarization flip talk(17th) X. Li iv) High polarization v) Low energy operation Undulator-base e+ : need deceleration Laser-base e+ : no problem

  8. Why Laser-Compton ? i) Positron Polarization. ii) Independence Undulator-base e+ : use e- main linac Problem on design, construction, commissioning, maintenance, Laser-base e+ : independent Easier construction, operation, commissioning, maintenance iii) Polarization flip @ 5Hz (for CLIC @ 50 Hz) iv) High polarization v) Low energy operation Undulator-base e+ : need deceleration Laser-base e+ : no problem vi) Synergy in wide area of fields/applications

  9. Status of Compton Source Proof-of-Principle demonstration was done. ATF-Compton Collaboration Polarized -ray generation: M. Fukuda et al., PRL 91(2003)164801 Polarized e+ generation: T. Omori et al., PRL 96 (2006) 114801

  10. Status of Compton Source Proof-of-Principle demonstration was done. ATF-Compton Collaboration Polarized -ray generation: M. Fukuda et al., PRL 91(2003)164801 Polarized e+ generation: T. Omori et al., PRL 96 (2006) 114801 We still need many R/Ds and simulations. Many Talks in this Workshop

  11. Status of Compton Source Proof-of-Principle demonstration was done. ATF-Compton Collaboration Polarized -ray generation: M. Fukuda et al., PRL 91(2003)164801 Polarized e+ generation: T. Omori et al., PRL 96 (2006) 114801 We still need many R/Ds and simulations. Many Talks in this Workshop We have 3 schemes. Choice 1 : How to provide e- beam Storage Ring, ERL, Linac Choice 2 : How to provide laser beam Wave length (=1m or =10m ) staking cavity or non stacking cavity Choice 3 : e+ stacking in DR or Not

  12. Laser Compton e+ Source for ILC/CLIC We have 3 schemes. 1. Ring-Base Laser Compton Storage Ring + Laser Stacking Cavity (=1m), and e+ stacking in DR S. Araki et al., physics/0509016 2. ERL-Base Laser Compton ERL + Laser Stacking Cavity (=1m), and e+ stacking in DR 3. Linac-Base Laser Compton Linac + non-stacking Laser Cavity (=10m), and No stacking in DR Proposal V. Yakimenko and I. Pogorersky T. Omori et al., Nucl. Instr. and Meth. in Phys. Res., A500 (2003) pp 232-252

  13. Laser Compton e+ Source for ILC/CLIC We have 3 schemes. 1. Ring-Base Laser Compton Storage Ring + Laser Stacking Cavity (=1m), and e+ stacking in DR S. Araki et al., physics/0509016 2. ERL-Base Laser Compton ERL + Laser Stacking Cavity (=1m), and e+ stacking in DR 3. Linac-Base Laser Compton Linac + non-stacking Laser Cavity (=10m), and No stacking in DR Proposal V. Yakimenko and I. Pogorersky T. Omori et al., Nucl. Instr. and Meth. in Phys. Res., A500 (2003) pp 232-252 Good! But we have to choose!

  14. Ring/ERL Scheme for ILC

  15. Ring/ERL Scheme for ILC ILC requirement Ne+/bunch = 2 x 1010 Nbunch / train = 3000 Rrep_train = 5 Hz

  16. Ring/ERL Compton Re-use Concept laser pulse stacking optical cavities Re-use photon beam positron stacking in main DR Electron storage ring, or Energy Recovery Linac Re-use electron beam, or Re-use energy of beam to main linac

  17. 325 MHz 325 MHz Optical Cavity for Pulse Laser Beam Stacking Reuse high power laser pulse by optical cavity Laser-electron small crossing angle Laser bunches Lcav = n  Lcav = m Llaser Cavity Enhancement Factor = 1000 - 105

  18. Compton scattering of e- beam stored in storage ring off laser stored in Optical Cavity. 5.3 nC 1.8 GeV electron bunches x 5 of 600mJ stored laser -> 2.3E+10 γ rays -> 2.0E+8 e+. By stacking 100 bunches on a same bucket in DR, 2.0E+10 e+/bunch is obtained. Electron Storage Ring 1.8 GeV 1.8 GeV booster Compton Ring Scheme for ILC

  19. Compton Ring Scheme for ILC Compton scattering of e- beam stored in storage ring off laser stored in Optical Cavity. 5.3 nC 1.8 GeV electron bunches x 5 of 600mJ stored laser -> 2.3E+10 γ rays -> 2.0E+8 e+. By stacking 100 bunches on a same bucket in DR, 2.0E+10 e+/bunch is obtained. Electron Storage Ring 1.8 GeV 1.8 GeV booster Parameter Set is Just an Example Will be changed by the feedback from R/Ds.

  20. ERL scheme for ILC High yield + high repetition in ERL solution. 0.48 nC 1.8 GeV bunches x 5 of 600 mJ laser, repeated by 54 MHz -> 2.5E+9 γ-rays -> 2E+7 e+. Continuous stacking the e+ bunches on a same bucket in DR during 100ms, the final intensity is 2E+10 e+. Conversion Target To Positron Liniac Photon Capture System Laser Optical Cavities RF Gun Dump SC Linac 1.8 GeV 1000 times of stacking in a same bunch

  21. ERL scheme for ILC High yield + high repetition in ERL solution. 0.48 nC 1.8 GeV bunches x 5 of 600 mJ laser, repeated by 54 MHz -> 2.5E+9 γ-rays -> 2E+7 e+. Continuous stacking the e+ bunches on a same bucket in DR during 100ms, the final intensity is 2E+10 e+. Conversion Target To Positron Liniac Photon Capture System Laser Optical Cavities RF Gun Dump SC Linac 1.8 GeV Parameter Set is Just an Example Will be changed by the feedback from R/Ds. 1000 times of stacking in a same bunch

  22. Conversion Target To Positron Liniac Photon Capture System Laser Optical Cavities RF Gun Dump SC Linac 1.8 GeV Electron Storage Ring 1.8 GeV 1.8 GeV booster Ring scheme and ERL scheme are SIMILAR Ring Scheme ERL scheme

  23. What is the Difference? : Ring and ERL What is Reused Ring: Electron Beam ERL: Energy of the electron beam

  24. What is the Difference? : Ring and ERL What is Reused Ring: Electron Beam ERL: Energy of the electron beam Collision / Operation Ring: Burst Collision (need cooling time) ERL: as CW as possible

  25. What is the Difference? : Ring and ERL What is Reused Ring: Electron Beam ERL: Energy of the electron beam Collision / Operation Ring: Burst Collision (need cooling time) ERL: as CW as possible Bunch Length Ring: Naturally Long (typically 30 psec) ERL: Short (can be less than 1 p sec)

  26. What is the Difference? : Ring and ERL What is Reused Ring: Electron Beam ERL: Energy of the electron beam Collision / Operation Ring: Burst Collision (need cooling time) ERL: as CW as possible Bunch Length Ring: Naturally Long (typically 30 psec) ERL: Short (can be less than 1 p sec) Bunch Charge Ring: Larger ERL: Smaller

  27. Parameters and Choices of Ring/ERL scheme

  28. Ring Scheme Parameters

  29. Ring Scheme Parameters Burst Operation of Laser (Burst Collision) Need to cool Compton Ring Good for stacking in DR Cooling time ~ 10 m sec Ng / bunch = 2.3 x 1010 simulation by CAIN E=1.8 GeV, 0.6 J x 5 CP (assume) Ne-/ bunch = 3.3 x1010 (5.3 nC / bunch) (assume) Bunch length ~ 1 p sec (assume) Ne+/ bunch = 2 x 108 Ne+(captured) / Ng = 0.8 % (assume) We need 100 times of stacking in a same DR bunch. {10 stacking (<<1 ms) + cooling (~10 ms) } x 10 Burst Operation of Laser --> Burst Amplifier ? --> talk M. Fukuda (18th)

  30. Ring Scheme Parameters Burst Operation of Laser (Burst Collision) Need to cool Compton Ring Good for stacking in DR Cooling time ~ 10 m sec Ng / bunch = 2.3 x 1010 simulation by CAIN E=1.8 GeV, 0.6 J x 5 CP (assume) Ne-/ bunch = 3.3 x1010 (5.3 nC / bunch) (assume) Bunch length ~ 1 p sec (assume) Ne+/ bunch = 2 x 108 Ne+(captured) / Ng = 0.8 % (assume) We need 100 times of stacking in a same DR bunch. {10 stacking (<<1 ms) + cooling (~10 ms) } x 10 Burst Operation of Laser --> Burst Amplifier ? --> talk M. Fukuda (18th)

  31. Ring Scheme Parameters Bunch Length in the Compton Ring Bunch Length 30 ps & finite X-angle --> Lose luminosity Short Bunch ? Bunch Compress --> CPs --> Decompress ? too difficult ? Very Small Momentum Compaction Factor ? beam dynamics --> talks P. Gladkikh, E. Bulyak Crab Crossing ? Head on Collision? We need mirrors with a hole. --> Non Stacking Laser Cavity --> Linac Scheme Ne / bunch Ne / bunch = 3.3 x 1010 ( 5.3 nC/bunch) Reasonable Feasibility?

  32. ERL Scheme Parameters

  33. Choice of ERL parameters I = 26 mA (a) Ne/bunch = 1 x 109 Tb_to_b = 6.15 ns (160 pC x 160 MHz) (b) Ne/bunch = 3 x 109 Tb_to_b = 18.5 ns (480 pC x 54 MHz) (c) Ne/bunch = 1 x 1010 Tb_to_b = 61.5 ns (1.6 nC x 16 MHz) (d) Ne/bunch = 3 x 1010 Tb_to_b = 185 ns (4.8 nC x 5.4 MHz)

  34. more difficult Choice of ERL parameters I = 26 mA (a) Ne/bunch = 1 x 109 Tb_to_b = 6.15 ns (160 pC x 160 MHz) (b) Ne/bunch = 3 x 109 Tb_to_b = 18.5 ns (480 pC x 54 MHz) (c) Ne/bunch = 1 x 1010 Tb_to_b = 61.5 ns (1.6 nC x 16 MHz) (d) Ne/bunch = 3 x 1010 Tb_to_b = 185 ns (4.8 nC x 5.4 MHz)

  35. Choice of ERL parameters I = 26 mA (a) Ne/bunch = 1 x 109 Tb_to_b = 6.15 ns (160 pC x 160 MHz) (b) Ne/bunch = 3 x 109 Tb_to_b = 18.5 ns (480 pC x 54 MHz) (c) Ne/bunch = 1 x 1010 Tb_to_b = 61.5 ns (1.6 nC x 16 MHz) (d) Ne/bunch = 3 x 1010 Tb_to_b = 185 ns (4.8 nC x 5.4 MHz) I = 80 mA (too ambitious !?) (e) Ne/bunch = 3 x 109 Tb_to_b = 6.15 ns (480 pC x 160 MHz) (f) Ne/bunch = 1 x 1010 Tb_to_b = 18.5 ns (1.5 nC x 54 MHz) (g) Ne/bunch = 3 x 1010 Tb_to_b = 61.5 ns (4.8 nC x 16 MHz)

  36. Choice of ERL parameters I = 26 mA (a) Ne/bunch = 1 x 109 Tb_to_b = 6.15 ns (160 pC x 160 MHz) (b) Ne/bunch = 3 x 109 Tb_to_b = 18.5 ns (480 pC x 54 MHz) (c) Ne/bunch = 1 x 1010 Tb_to_b = 61.5 ns (1.6 nC x 16 MHz) (d) Ne/bunch = 3 x 1010 Tb_to_b = 185 ns (4.8 nC x 5.4 MHz) more difficult I = 80 mA (too ambitious !?) (e) Ne/bunch = 3 x 109 Tb_to_b = 6.15 ns (480 pC x 160 MHz) (f) Ne/bunch = 1 x 1010 Tb_to_b = 18.5 ns (1.5 nC x 54 MHz) (g) Ne/bunch = 3 x 1010 Tb_to_b = 61.5 ns (4.8 nC x 16 MHz)

  37. Choice of ERL parameters I = 26 mA (a) Ne/bunch = 1 x 109 Tb_to_b = 6.15 ns (160 pC x 160 MHz) (b) Ne/bunch = 3 x 109 Tb_to_b = 18.5 ns (480 pC x 54 MHz) (c) Ne/bunch = 1 x 1010 Tb_to_b = 61.5 ns (1.6 nC x 16 MHz) (d) Ne/bunch = 3 x 1010 Tb_to_b = 185 ns (4.8 nC x 5.4 MHz) I = 80 mA (too ambitious !?) (e) Ne/bunch = 3 x 109 Tb_to_b = 6.15 ns (480 pC x 160 MHz) (f) Ne/bunch = 1 x 1010 Tb_to_b = 18.5 ns (1.5 nC x 54 MHz) (g) Ne/bunch = 3 x 1010 Tb_to_b = 61.5 ns (4.8 nC x 16 MHz)

  38. I = 26 mA (assume) Rrep (MHz) 160 54 16 Ne- /bunch 1 x 109 3x109 1x1010 Necessary N stack 3300 1000 330 ERL repetition (Rrep = 1/Tb_to_b ) ERL repetition and e+ Stacking How many stacks do we need ? Number of gamma-rays Ng/ bunch = 0.75 x 1010 simulation by CAIN assume E=1.8 GeV, 0.6 J x 5 CP, Ne=1x1010 Number of positrons Ne+/ bunch = 0.6 x 108 assume Ne+(captured) / Ng = 0.8 %

  39. I = 26 mA (assume) Rrep (MHz) 160 54 16 Ne- /bunch 1 x 109 3x109 1x1010 Necessary N stack 3300 1000 330 Max N stack 5000 1600 500 ERL repetition (Rrep = 1/Tb_to_b ) continued ERL repetition and e+ Stacking (continued) Max N stack is limited by time. T stack < 100 m sec T stack = 3000 bunches x N stack / Rrep Max N stack is limited by DR. How many stacks can we achieve ? --> Need study --> talk F. Zimmermann

  40. ERL repetition (Rrep = 1/Tb_to_b ) continued ERL repetition and Laser Rrep (MHz) 160 54 16 L cavity (round trip)(m) 1.9 5.6 19 L cavity (end-to-end*)(m) 0.46 1.4 4.6 Reasonable size of stacking cavity? Reasonable size of laser oscillator? * assume 4-mirror cavity

  41. Necessary R/Ds for Ring / ERL scheme

  42. Ring / ERL scheme R&D List e+ stacking in DR talk F. Zimmermann simulation studies talks P. Gladkikh, E. Bulyak Compton Ring simulation studies ERL simulation studies e+ capture (common in all e+ sources) Simulation study talk A. Vivoli talk T. Kamitani Collaboration with KEKB upgrade e+ production target talks E. Bulyak Laser Fiber laser / Mode-lock laser talk E. Cormier Laser Stacking Cavity talks X. Li, F. Zomer, R. Chiche H. Shimizu, Y. Ushio, S. Miyoshi experimental and theoretical studies

  43. Prototype Cavities Just Example 2-mirror cavity 4-mirror cavity (LAL) (Hiroshima / Weseda / Kyoto / IHEP / KEK) moderate enhancement moderate spot size simple control high enhancement small spot size complicated control

  44. Prototype Cavities Just Example 2-mirror cavity 4-mirror cavity (LAL) (Hiroshima / Weseda / Kyoto / IHEP / KEK) moderate enhancement moderate spot size simple control high enhancement small spot size complicated control talk (17th) --> X. Li talks (17th) --> R. Chiche F. Zomer talks (18th) --> H. Shimizu, Y. Ushio, S. Miyoshi

  45. Applicationsand PosiPol Collaboration

  46. World-Wide-Web of Laser Compton

  47. World-Wide-Web of Laser Compton talk(18th) R. Hajima

  48. World-Wide-Web of Laser Compton talk(18th) M. Fukuda

  49. World-wide PosiPol Collaboration Collaborating Institutes: BINP, CERN, DESY, Hiroshima, IHEP, IPN, KEK, Kyoto, LAL, CELIA/Bordeaux,NIRS, NSC-KIPT, SHI, Waseda, BNL, JAEA and ANL Sakae Araki, Yasuo Higashi, Yousuke Honda, Masao Kuriki, Toshiyuki Okugi, Tsunehiko Omori, Takashi Taniguchi, Nobuhiro Terunuma, Junji Urakawa, Yoshimasa Kurihara, Kazuyuki Sakaue, Masafumu Fukuda, Takuya Kamitani, X. Artru, M. Chevallier, V. Strakhovenko, Eugene Bulyak, Peter Gladkikh, Klaus Meonig, Robert Chehab, Alessandro Variola, Fabian Zomer, Alessandro Vivoli, Richard Cizeron, Viktor Soskov, Didier Jehanno, M. Jacquet, R. Chiche, Yasmina Federa, Eric Cormier, Louis Rinolfi, Frank Zimmermann, Kazuyuki Sakaue, Tachishige Hirose, Masakazu Washio, Noboru Sasao, Hirokazu Yokoyama, Masafumi Fukuda, Koichiro Hirano, Mikio Takano, Tohru Takahashi, Hirotaka Shimizu, Shuhei Miyoshi, Yasuaki Ushio, Akira Tsunemi, Ryoichi Hajima, Li XaioPing,Pei Guoxi,Jie Gao, V. Yakinenko, Igo Pogorelsky, Wai Gai, and Wanming Liu POSIPOL 2006 CERN Geneve 26-27 April POSIPOL 2007 LAL Orsay 23-25 May POSIPOL 2008 Hiroshima 16-18 June http://posipol2006.web.cern.ch/Posipol2006/ http://events.lal.in2p3.fr/conferences/Posipol07/ http://home.hiroshima-u.ac.jp/posipol/

  50. 1. Laser-Compton has a large potential as a future technology. 2. Many common efforts can be shared in a context of various applications. – Compact and high quality X-ray source for industrial and medical applications – -ray source for disposal of nuclear wastes – Beam diagnostics with Laser – Laser Cooling – Polarized Positron Generation for ILC and CLIC –  collider PosiPol-Collaboration

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